Detergent



United States Patent 3,427,248 DETERGENT Vincent Lamberti, Upper Saddle River, and Henry Lemair, Leonia, N.J., assignors to Lever Brothers Company, New York, N.Y., a corporation of Maine No Drawing. Filed Oct. 22, 1965, Ser. No. 502,299 US. Cl. 252-117 7 Claims Int. Cl. Clld 9/32, 9/30, 9/02 ABSTRACT OF THE DISCLOSURE The specification is concerned with certain polyolethers, polyolpolyethers or sulfur analogs thereof which can be used alone as a detergent or in combination with other compounds.

This invention relates to a detergent. More particularly, it is concerned with a detergent which is a polyolether, polyolpolyether or sulfur analog thereof.

In the past, a straight chain or branched chain alcohol may be reacted with ethylene oxide to form ethoxylates, such as n-tetradecyl alcohol-7 moles ethylene oxide, dodecyl alcohol-1O moles ethylene oxide and Sterox AJ (tridecyl alcohol-about 9.5 moles ethylene oxide). These ethoxylates have detergent properties.

It has now been discovered that certain polyolethers and polyolpolyethers and thioether analogs are surface active agents, e.g., detergent actives, dishwashing detergents, lime-soap dispersants and suds-boosters for other detergent actives. The compounds of the invention also have antimicrobial activity and are nontoxic, mild towards skin and completely biodegradable.

method, the compounds of the invention are the reaction products of:

R (bu Hz HzC (II) with:

HZ(CH C'H(OH)R (III) wherein R, a, b and R are as defined heretofore and Z is oxygen or sulfur. If the reaction product is a thioether, it can be oxidized, for example with t-butyl hydroperoxide in methanol, to form the corresponding sulfoxide. It is also possible to react either a long-chain diol or a monoalkyl ether of glycerol with one molar proportion of ethylene oxide. By this process however, a mixture of products is obtained containing large proportions of unreacted starting diol or ether, with some mono-ethoxylated compound with which this invention is concerned, and with some poly-ethoxylated compounds such as those rep resented by the formula RCH(OH)CH O (CH CH O) H wherein x is greater than 1.

If .a long-chain epoxyalkane is a reactant, it may be obtained by any suitable method. For example, an alkene may be oxidized directly in the presence of a catalyst or a chlorhydrin may be reacted with sodium hydroxide. Similarly, if a long-chain diol is a reactant, it may be obtained by any suitable method, such as the oxidation and hydration of olefins and the hydrolysis of chlorhydrins.

The following short-chain polyhydroxy reactants among others are within the scope of the above structure I:

SHORT-CHAIN POLYHYDROXY REACTANT (STRUCTURE III) a R Z Name Structure 1 H 0 Ethylene glycol HOCHZOHQOH 1 CHzOH o Glycerol Hoomcmomomorr 1 CH; O 1,2-propanediol HOCHzC OHCH:

1 H S 2-rnereapto ethanol HSOHZCH2OH 1 CHZOH S 3-mereapto-1,2-propanediol HSCHzCH(OH)CH2OH 1 CH; 8 l-mercapto-Z-propanol HSCHzCHOHCHa 2 omen o 1,2,4-butane trlol HOCHzCHzCHwEDOH OH 2 CH3 0 1,3-butylene glycol HOCHzCH2CH(OH)CHa 2 H S 3-mercapto-1-propanol HSCH2CH2CH2O 2 CHzOH S 4-mercapto-l,2-butauediol HSCH2CH2CE(OH)0H2OH 2 011:! S 4-mercapto-2-butanol HSOHzCHzOH(OH)OH3 These new nonionic detergents have the following ge- Preferred compounds in this invention among others neric structure: include polyolethers, such as 2-hydroxydodeeyl 2'-hydroxyethyl ether having the structure: CH (OH2)0CHOH2OCH2CH2OH )b H and Z-hydroxydodecyl glyceryl ether having the structure:

I HG lkwmhomommmwm CH:(CH2)DCHCH2OCH2CHCH2 H2 -[z(0H2).oH(oH)R 1.1011]m (I) H 0H 0H wherein R is an aliphatic hydrocarbon group having 5-12 and polyolpolyethers, such as a-decyl-a'-hydroxyethyl carbon atoms; each Z is oxygen, sulfur or snlfoxide; a is 1 30 glyceryl diether having the structure: or 2; b is 0 or 1; m is 0 or 1; n, is 0 or 1; ml+n is 1; and CH (CHz)aCH 0CH CHCHZOCH on on R is H, CH OH or CH As used herein, this structure a 2 is intended to include isomeric compounds. OH

Any known method may be employed to prepare the The compounds of the present mventlon may be used aforementioned polyolethers and polypolyethers and sulfur alone as detergents. However, the compounds of the inanalogs thereof. However, the preferred method is to react vention may also be used in combination with other a long chain epoxide or long chain glycidyl ether with a detergents. Examples of detergent compounds with which polyhydroxy compound, such as, ethylene glycol or glycthe compounds of the invention may be admixed to form erol, in the presence of an :acid catalyst, e.g., SnCl or a superior combinations are the well-known anionic types basic catalyst, e.g., NaOCH The reaction can also be represented by the water-soluble and Water-dispersible carried out without a catalyst, but in such cases, longer reaction times are required. In accordance with this organic surface-active agents having in the molecule a hydrophobic group of about 8 to about 22 carbon atoms and a hydrophilic sulfate, sulfonate or carboxylic group having a cation which does not insolubilize the compound. The following anionic detergents among others are suitable for use with the compounds of the present invention:

(1) Alkylbenzenesulfonates, such as the sodium and potassium salts having a branched or straight chain alkyl portion of about 9 to about 15 carbon atoms.

2) Alkyl sulfates, such as the sodium and triethanolam monium salts of C -C alkyl sulfuric acid, prepared by sulfating the alcohols derived from coconut oil or tallow, or prepared synthetically.

(3) The alkali metal and ammonium salts of the sulfated ethoxylates of a long-chain alcohol and 3 to molar proportions of ethylene oxide, for example the ammonium salt of an ethoxylate containing an average of 3.1 molar proportions of ethylene oxide and 1 mole of an alcohol mixture known commercially as Alfol 1412, composed of about /a n-tetradecanol and about /s n-dodecanol.

(4) The compounds known as Medialans, which are amido carboxylic acids formed by condensing fatty acids of C -C chain length with sarcosine, CH NHCH COOH. Generally the alkali metal and basic nitrogen-radical salts are employed.

(5) Alkanesulfonates, such as ammonium dodecanesulfonate.

(6) Alkoxyhydroxypropanesulfonates, such as the water-soluble salts of 3-dodecyloxy-2-hydroxy-l-propanesulfonate.

(7) Soaps, the surface-active substances formed usually by the reaction of caustic alkalies with natural glyceridic fats and oils, generally prepared in high purity, and having the generic molecular formula RCOONa, wherein R is a straight-chain hydrocarbon group having from about 8 to about 22 carbon atoms.

The compounds of the invention are also suds-boosters for nonionic detergents. The following nonionic detergents among others are suitable for use with the compounds of the present invention.

1) The Pluronics, tformed .by condensing propylene oxide with propylene glycol to a molecular weight of about 600-2500 to form a base followed by condensing ethylene oxide to this base to the extent of about 10% to about 90%, total molecule basis. US. Pat. Nos. 2,674,619 and 2,677,700 describe operable nonionic compounds.

(2) Compounds formed by the simultaneous polymer ization of propylene oxide and ethylene oxide, and containing randomly positioned oxypropylene and oxyethylene groups. These and related compounds are described in US. Pats. Nos. 2,979,528, 3,036,118, 3,022,335, 3,036,130 and 3,048,548.

(3) Alkyl phenols having 9-12 carbon atoms in the alkyl portion (straight or branched) ethoxylated with 410 molar proportions of ethylene oxide.

(4) Ethoxylates of fatty alcohols having 8-18 carbon atoms per molecule and 5 to 30 molar proportions of oxyethylene groups.

The compounds of this invention may interact synergistically with all suds-producing anionic and nonionic surface-active substances to provide mixtures having improved properties beyond those expected on the basis of the properties of the individual components of the mixture. With nonsoaps, the synergism may be evident in suds production or stability. With soaps, the synergism may be evident in the form of reduced lime-scum formation.

Thus, in accordance with this invention, new compounds have been formed. The compounds of the present invention have certain noteworthy features. For example, the synergistic suds-producing properties of the compounds with other detergents and sudsing agents are surprising. The antimicrobial properties of the compounds are also surprising. Furthermore, the compounds of the invention are nonionic surfactants with foaming characteristics superior to both well-known anionic and nonionic detergents. The ability to formulate a detergent based on the nonionic materials of the invention having high foaming or dishwashing characteristics with built-in germicidal properties and which at the same time is biodegradable by sewage or natural water bacteria is certainly surprising and unexpected.

The following examples are submitted to illustrate but not to limit this invention. Unless otherwise indicated, all parts and percentages in the specification and claims are based upon weight.

EXAMPLE I A compound, 2.-hydroxy-C alkyl glyceryl ether, was prepared by adding 286 g. (1.3 moles) of 1,2-epoxy-C alkane (purity, 89%) dropwise over 30 minutes with stirring at -137 C. to 2401 g. (26 moles) of glycerol containing 2.3 g. of stannic chloride. Heating was continued .for one hour. The upper layer was removed and an additional 286 g. of epoxide was added to the lower, glycerol, layer at 133-138 and heating continued for one hour. The first product layer was then returned to the pot and the combined layers neutralized with 5 g. of sodium carbonate. The layers were then separated, and from the top layer olefin, unreacted epoxide, and excess glycerol were removed by distillation at 0.9 mm. Distillation of the 691 g. residue in a molecular still gave 488 g. (1.67 moles) of distilled product.

A compound, 2-hydroxydodecyl 2'-hydroxyethyl ether, was prepared as follows. A solution of 1 ml. stannic chloride in 434 g. (7.0 moles) ethylene glycol was stirred at 135150 C. while 129 g. (0.63 mol; 90% purity) 1,2-epoxydodecane were added dropwise over a thirty minute period. The solution was held at about C. for an additional hour after which a solution of 8 g. sodium carbonate in 32 g. water was added to neutralize the catalyst. The reaction product therefrom was stripped of excess ethylene glycol (up to 109 C. at 16 mm.). The crude product remaining was filtered and distilled subsequently at reduced pressure.

These two compounds and one prior art compound were tested for detergency by means of a Terg-O-Tometer Detergency Test. This test gives an empirical measurement of the amount of soil removed from fabric under simulated washing conditions. Stated sizes of cotton cloth, soiled in a standard manner with a standard soil, i.e., vacuum cleaner dust, are placed in a miniature washing machine, and they are laundered in the presence of a measured amount of detergent and water of a standard hardness. A Terg-O-Tometer apparatus is described in the Journal of the American Oil Chemists Society, vol. 27, pages 153159, May 1950. After rinsing and drying, the reflectance of the cloths is measured and compared with the reflectance of the soiled cloths before washing.

In the detergency tests referred to herein, the Terg-O- Tometer apparatus was maintained in a water bath adjusted to maintain the temperature of the washing solution at 120 F.i2 F. The paddle oscillation was brought to ninety complete cycles per minute, and the paddle oscillated through a 320 arc.

With agitators in position on the machine, the detergent was added in the desired amount to the washpot of the machine. Subsequently, 1250 ml. of water, having a hardness of 180 parts per million as CaCO (60 parts magnesium and 120 parts calcium calculated as calcium carbonate), were added. The machine was started and the solution agitated until the detergent was dissolved. Four pieces of soiled cloth heretofore described approximately 4 /2 inches x 6 inches were then added and washing was continued for twenty minutes, after which the test swatches were removed from the solution and hand-squeezed. The washpot was refilled with clear rinse water of the same hardness used for washing at a temperature of 120 F., 2 F., and, with the agitators running, the cloths were rinsed for five minutes. The cloths were then removed, hand-squeezed and ironed dry. The detergency units were determined by recording the differences in reflectance readings for washed and unwashed soiled cloths. Table 1 indicates the results of the Terg-O-Tometer tests.

Sodium mixed C C alkylbenzene sulfonate 2 6.9

0.025% compound and 0.05% tetrapotassium pyrophosphato (TKPP).

3 Derived from tetraand penta-propylene.

This example shows that the compounds of this inven- 6 TABLE 3 Number of Compound: plates washed Z-hydroxydecyl 2'-hydroxyethyl ether 25 2-hydroxydodecyl 2-hydroxyethyl ether 33 This example demonstrates that compounds of the invention have excellent dishwashing properties.

EXAMPLE IV The dishwashing properties of the ethylene glycol ether tion in built. formulations have supgrior T3 10 of Example I with (Formulation A) and without (Formucompared Wlth a Prior compoun used m ouse lation B) a booster were measured by determining the detergent formulatlons' number of dishes washed with 6 g. of each formulation EXAMPLE II in 6 quarts of 120 p.p.m. water at 116 F. Table 4 has A compound, 2-hydroxydodecyl alkyl glyceryl ether, the results was prepared by adding 160 g. (0.87 mol) 1,2-epoxy- TABLE 4 dodecane dropwise over 50 minutes with stirring at 125 Formulation C. to 400 grams (4.35 moles) glycerol (synthetic grade, Ingredients (parts by wt.) min. 99.5%) containing 1.7 g. stannic chloride. Shortly A B after addition had started, the solution became cloudy and two phases developed subsequently. The solution was i;oii fitigggfifiaiolhiifiiiffffifffff::::::j: f? stirred two additional hours. The catalyst was then new Number Dishes Washed 32 41 tralized by the addition of 4 g. sodium bicarbonate in 200 ml. water and the product was taken up in water and From thls f" 1t 15 ,mamfest that compqunds ether. The ether layer was washed and dried, and the m the SFOPB of the i efcenent dlshwashmg solvent was removed therefrom followed by vacuum dis- Propemes alone or combmatlon wlth a boostertillation.

The dishwashing properties of this compound and the EXAMPLE V compound, 2-hydroxydodecyl 2'-hydroxyethyl ether of The compound, u-decyl-u-hydroxyethyl glyceryl di- Example were p d wi h three pri r art comether, was prepared by the addition of g. (0.16 mole) pounds by determining the number of plates washed with decyl glycidyl ether to g. (0.65 mole) ethylene glycol 1.5 g. of each compound In 6 quarts of 120 P-Pm- Water containing 0.2 ml. of stannic chloride at 125 C. over at 116 F. The results a shown In Table 0.5 hour. The solution was stirred an additional hour at TABLE 2 135 C. Sodium carbonate was added to destroy the cat- 35 o Number f alyst, excess glycol was stripped 01f, and the residue was Compound: plates washed distilled- 2-hydroxydodecyl glyceryl ether 31 The e y glycol ether of Example I was p p 2-hydroxydodecyl 2'-hydroxyethy1 ether 28 and a s1m1lar ethylene glycol ether was also prepared ex- Dodecylpheno1-10 ethylene oxide 1 5 4O cept that one of the reactants was 1,2-ep0 y-C -C Sodium dodecylbenzene sulfonate 17 alkane. Sodium lauryl sulfate 5 These three compounds were tested as suds-boosters 1 nodecyl chain is derived from propylene tetramer; ethy1 for other detergent actives 1nd1cated in Table 5. The numene oxide chain averages 10 units in length; ber of dishes washed for each of the various formulatlons ci nie sownicmomn was determined as described in Example IV. The results 9 Dodecyl chain is derived from propylene tetramer. are also mdlcated in Table TABLE 5 Ingredients Formulation (parts by wt.)

ABCDEFGHIJKLM Ammonium Aliol 1412-31 E0 sulfate 1 30 30 30 Linear alkylate sulfonato 2 30 30 Sodium lauryl sulfate 3 30 30 2-hydroxy 011-1531ky1 "hYdl'OXY9t YI-Bthfil' 9 9 9 9 2-hydroxydodecyl2-hydroxyethyl ether 9 9 aDecyl-a-hydroxyethyl glyceryl diether 9 9 9 Number of Dishes Washed 23 8 3 35 32 28 8 3 42 45 17 10 39 Ammonium salt of a Suliated atoms in the hydrocarbon chain.

reaction product of 3.1 molar proportions of ethylene oxide and 1 mole of a mixture of long cham primary alcohols 01 which about has 14 carbon atoms and about 36 has 12 carbon ?Sodium alkylbenzenesulfonate in which the alkyl portion is a linear hydrocarbon chain composed of a mixture of chain lengths of about 11 to about 14 carbon atoms (LAS). 8 Sodium salt of sulfated primary alcohols derived from coconut oil.

It is evident from this example that the reaction products of 1,2-epoxydodecane have greatly superior dishwashing properties in relation to the standard detergents.

EXAMPLE *III It is manifest from the above that the compounds of the present invention are good suds-boosters and have a synergistic efiect. This is shown by the 35 dishes washed with Formulation D whereas 31 total dishes were washed by Formulations A and B, by the 32 dishes washed with Formulation E whereas 26 total dishes were washed by Formulations A and C, by the 42 dishes washed with Formulation I whereas 36 total dishes were washed by Formulations F and G, by the 45 dishes washed with Formulation J whereas 31 total dishes were washed by Formulations F and H and by the 39 dishes washed with Formulation M whereas 27 total dishes were washed by Formulations K and L. Duplicate controls, which were 7 8 a commercial liquid dishwashing detergent, were run, and propriate 1,2-epoxyalkane reactant was used and the ap- 33 and 36 dishes were washed with the two controls. propriate glycol or glycerol reactant was used.

EXAMPLE 1 The lime-soap scum dispersion test consists of agitating 35 cc. of a 1% (soap plus agent) solution at 45 C. in formulations Shown in Table 6 5 a Waring Blendor for one minute at 8,500 r.p.m. After The results in Table 6 demonstrate that compounds 30 g f' z i g f g within the purview of the invention are good dishwashing g) Wflter at e mlxtum t en The procedure of Example V was repeated with the detergents by themselves and are good suds-boosters for surfed for 90 secPnds with a mechanical stirrer after other detergent actives. Three runs were made with a com- Whlch the System rated for foam- It finally filtered mercial liquid dishwashing detergent as a control, and 35, 10 Over a la th and the reflectance is read on the 35 and 38 dishes were washed. Hunter Refiectometer.

TABLE 6 Formulation (parts by wt.)

A B C D E F G H I Ammonium dodecylbenzene sulionate of Example II 17 17 17 Ammonium Altol 14123.1 E0 sulfate of Example V .o 25 25 25 25 2-hydroxydodecyl glyceryl ether of Example 11 10 25 10 Z-hydroxytetradecyl glyceryl ether 1 o r 10 10 Z-hydroxy On-is alkyl glyceryl ether of Example I- Z-hydroxydodecyl 2-hydroxyethyl ether of Example 2-hydroxy 011-15 alkyl 2-hydroxyethyl ether Number of Dishes Washed Ingredients 1 Prepared in the same manner as the glyceryl ether of Example II except that 1,2-ethoxytetradecane was the reactant.

EXAMPLE VII The properties of each of the above compounds are Formulation A was provided with the following ingre- Table dients therein: TABLE 8 TABLE 7 Percent l Foam Reflectance Ingredients: Percent Increase 6 Ammonium lauryl sulfate 13.2 confound: 20 H 0 so 7 2-hydroxy-C C alkyl 2hydroxyethyl 15 5 ether 4.0 20 2. 5 1. 1 2 4. 1.3 Olerc isopropanolamrde 1.0 g 2 Perfume 0.7 20 4. 3. 7 Water (balance to 100% 1 Percent compound=g. compound/(g. compound+g. soap) 100- concentration (compound+soap)=1%; soap is 80:20 sodium tallow; coconut soap used in the form of 87% soap, 13% water soap chips. Formulation A was found to be a good shampoo. The gfggggh 4: lathering, ease of wet and dry combing of the hair and Visualotfiervation and rating. hair conditioning were Similar to a Standard shampoo 5 Difierence between reflectometer readings on unwashed and washed h th F 1 cloth. The less the difierence, the greater is the efiectiveness of the agent formulation avmg 6 Same components ormu.atlo.n This example demonstrates that the compounds of the A except that the ether was replaced wrth capric d1- invention are effective lime-soap dispersants. ethanolamlde. EXAMPLE ]X By varying the 1,2-epoxyalkane and the appropriate glycol or glycerol (triol) reactant, Compounds A, B, C, D and E were formed as described in Example I. These Lime-soap dispersant properties were determined for compounds are as follows:

EXAMPLE VIII the following compounds: Compound structure A C1oH2i-C1HCHzOCHzCHOH2OH OH OH Compound Structure r y B C9-13H1927 CHCH2O CH2CHCH2OH A CmH25(| JHCH2OCHzCHCHzOH I OH OH OH O C1zH25-CHCH2O CHzCHCH:

H OH B CWHWEECHQO 0320B D CmHz1('3HGH2O omomom on H OH OH E CnHzv-CHCHzO CHzCHzCHCHg C CrzHzs-CHCHzO (31120112 OH OH OH OH Table 9 records the reflectance increase which was de- 5 termined as in Example VIII for each of the aforemen- D C1zHz5(iJHCH2OCHzCH2CH2 i d compounds.

OH OH TABLE 9 Compound: 1 Reflectance increase Control CrzHzsO CHzCHCHzOH Compounds A, B, C and D were prepared in the same Control of Example VIII manner as the ethers of Example I except that the ap- 20% as defined in Example VIII.

EXAMPLE X 10 Test and that two ethers of the invention were mild towards the skin in the RAP Mildness Test. Table 11 also shows that a shampoo formulation containing 2-hydroxydodecyl glyceryl ether was only moderately irritating in the Draize Rabbit Experiment Irritation Test and it would Riber Watef hiodegl'adatiofl l'ef Certain meet FDA corneal irritation requirements. Therefore, the q p un is within the scope of the mventlon and f Cercompounds within the scope of the present invention have tam previously kn own amomc and nomomc detergents. it bl t i it d ild g propertis The results are indicated In Table 10.

In this test, a new one-half gallon mason jar with metal EXAMPLE XII insert screw cap is rinsed with distilled water and 980 ml.

of freshly-sam l d rive wat i poured i t th j The germicidal activity of compounds described in this Twenty mg. of the test active is then added (as 20 ml, of invention were determined by the Streak Gradlent Plate a 1000 p.p.m. stock solution), resulting in a 20 mg./l. or Method- 20 p.p.m. solution. A magnetic bar is immediately placed 15 The Streak G t la e Me od 1 a m fica lon in the jar and the solution stirred for on minute a d of the gradlent plate method of Szybalsk1, Science, 116: sampled while the solution is still being stirred, The mag- 4548 for the determlnatloh 0f gefmlclde MEC netic bar is then removed and the top screwed on the jar. (Mlnlmum Effective Concentf atloI1) vahles- This method The jar remains quiescent at normal room temperature e p y streaks of Several Orgamsms P Plate.

until the next sampling. Sampling continues periodically AS demonstrated m Table Which lndlfifates the for the duration of the test, As many te t a tiv as d terminations, certain compounds of the invention have sursired, or as can be handled, may be run with the same basic p ely g antlmlcro'blal actlvlty a y are superwr river water; each test active requires a separate jar. At to p, C0Inm0I11Y used syllthehc detergent, a W?- each sampling, ml. are transferred to a 50 ml. graduated known anflflmgal g f and Well-known germlclde cylinder, shaken, and the foam height read in ml. 25 agalllst a number of mlcfool'gamsms- In view of Table 10, it is manifest that 2-hydroxydodecyl 1 2'-hydroxyethyl ether and Z-hydroxydodecyl glyceryl ether TABLE ACUTE ORAL TOXICITY TEST have excellent biodegradability since they lost all surface Compound 6 12:. Death activity in 3 or 4 days. Conversely, the previously known 5 nonionic detergents were still foaming after the fourth 2-hydroxytetradecy1 glyceryl ether 5.0 g./kg-.-- None. da. The dodecene-l derived stratigh; chaiingllkybenzene- RAP MILDNESS TEST 2 sn onate, a previous y nown io egra a e etergent,

Mild foamed less mltially than the compounds of the Invention, Fommlatlon g but showed no signs of degradation until the fourth day, in

1.30 2-hdr dd lle 1th inethleelool-.- 0-1 contrast to the compounds of the invention, whlch ex- ,31 ,432; j'g lf i gi ifig i f 5 in 0 1 e ano h1b1ted considerable degradation on the second day. 3 30% mm A1101 141%. IE 0 Sulfatein ethauoLwateL (H TABLE 10 4. 30% ammonium linear CnrCu alkylbenzene-sulfonate 3 Foam Heights in BIL/25 DRAIZE RABBIT EYE IRRITATION TEST 4 3 Compound ml. solution (D y 40 Ingredient Liquid Shampoo 0 1 2 3 4 (percent) 2-h droxydodecyl 2-hydroxyethyl ether 1 3y 3 1% 0 y y o yl g yc ryl ot er 25.0 2-hgdroxydodecylglycerylether 3% 3% 2 1 0 Perfume Cit-C15 straight chain alcohol, 60% ethylene 2 2 2 2 Water (balance to ffigfiji fig 'g"5 55515555155"51515; 36 1 Method given in Appraisal of the Safety of Chemicalsin Foods, Drugs ethylene oxide adduct 2% 3 2% 3 4 and Cosmetics by the stati of the Division of Pharmacology of the Food D de ne 1 derived Straight chain alkylbem $.61?! Dragwegdmimstration, Department of Health, Education and 1 1 e are mnmflfnmm 2 2A 3 2A 0 2 Method described by Justice, Travers and Vinson, Proceedings of the 1 AS in Example I Scientific Section of The Toilet Goods Association, Number 35, May 1961.

3 River water Die Away Tesm Mildness Batings with test level being 8% of formulation.

MPLE XI (1)=SNo efiudermal eros on gory x ma 818830 61'051011 all 955 E =2G5% tic 5%? epiiirmal eros(iotn (miaderattelty irgitating). I rea B! an el'OSlOl'l 5 long Y [IT]. a mg Toxlclty and m1l.dnesS .propertles were determmed for 4 Draize, J. H. Appraisal of the Safety of Chemicals in Foods, Drugs compounds Of the lnvention. The tests and the results Of and tc fsmhetics 195%. si lx albino rgbblits were 11338, E I {Left tgmflelxpgfiifi men 8. 8 81111300. 8.0 0 e SIX 81111118 5 receive O 8 the tests are hsted m Table strength solution in the left eye. N o rinse was used; the untreated eye Table 11 ShOWS that 110 rat deaths resulted Wlth 2-hyserved as a control. After 3 days, only one rabbit showed moderate corneal damage which persisted after the 7 day gross observation.

droxytetradecyl glyceryl ether in the Acute Oral Toxicity TABLE 12.GERMICIDAL ACTIVITY BY STREAK GRADIENT PLATE METHOD Compound Minimum Eiiective Concentration (MEG) in p.p.m.

C. albicans Chaet. globosum (y (mold) Test A:

2-hydroxydodecyl glyceryl other 42 28 Soap 5, 200 Syndet 2, 300 335 Triacetin 25, 000 3, 550

Str. Cami. Sal. S. aureus M. candidus faecalis albica'na E. colt choleraesuw Test B:

2-hydroxydodecyl glyceryl ether 37. 4 66. 5 30. 0 25. 6 100 100 Triehlorocarbanilide (TOG) 0. 15 100 100 100 100 100 C. albicans A. niger Test 0:

2-hydroxydodecyl 2-hydroxyethyl ether 38 36 a-Decyl-a'-hydroxyethyl lyceryl diether 100 72 2-hydroxydodecyl glycery ether 52 56 1 Commercial built detergent based on sodium mixed clfl'clfi polypropylenebeuzenesulfonate.

1 1 EXAMPLE x111 Compound A, 2-hydroxydodecyl 2-hydroxyethyl thio ether, was prepared by stirring a mixture of 25.3 g. (0.324 mol) 2-mercaptoethanol and 5.4 g. (0.1 mol) sodium methoxide under nitrogen while adding dropwise 59.6 g. (0.324 mol) 1,2-epoxydodecane over a period of 25 minutes. After continued stirring on a steam bath for 85 minutes, the crude material was dissolved in hexane. A portion therefrom was washed with water in the presence of methanol to remove catalyst and another portion was merely filtered.

Compound B, 2-hydroxy-C C alkyl 2'-hydroxyethyl thioether, was prepared in a same manner except that 1,2-epoxy C -C alkane was one of the reactants.

Compound C, a sulfoxide compound was formed by oxidizing 2 hydroxydodecyl 2' hydroxyethyl thioether with t-butyl hydroperoxide in methanol.

The dishwashing properties were determined by determining the number of plates washed in duplicate tests with 1.8 g. of each of the above compounds in 6 quarts of 120 p.p.m. water at 116 F. both with or without 0.54 g. of coconut fatt acid monoethanolamide (CMEA). The results are shown in Table 13.

TABLE 13 This example shows that the thioethers and the corre sponding sulfoxides within the purview of the present invention have excellent dishwashing properties.

Having set forth the general nature and specific embodiments of the present invention, the true scope is now particularly pointed out in the appended claims.

What is claimed is:

1. A composition consisting essentially of a surface active agent selected from the group consisting of an alkylbenzenesulfonate in which the alkyl group has 9 to 15 carbon atoms, an alkyl sulfate in which the alkyl group has 9 to 15 carbon atoms, an alkali metal or ammonium salt of the sulfated ethoxylates of a long chain alcohol and 3 to 5 molar proportions of ethylene oxide, amido carboxylic acids formed by condensing fatty acids of C -C chain length with sarcosine, an alkanesulfonate, an alkoxyhydroxypropane sulfonate, a soap, propylene oxide condensed with propylene glycol to a molecular weight of about 600-2500 further condensed with 10- 90% ethylene oxide, simultaneously polymerized propylene oxide and ethylene oxide containing oxypropylene and oxyethylene groups, an alkyl phenol ethoxylated with 4-10 molar proportions of ethylene oxide and an ethoxylate of a C C fatty alcohol and 5-30 molar proportions of oxyethylene groups and a detergent having the structure:

wherein R is an aliphatic saturated hydrocarbon group having 5-12 carbon atoms; Z is oxygen, sulfur or sulfox- 12 ide;ais1or2;mis0or1;nis0or1;m+nall occurrences is 1; and R is CH OH or CH 2. A composition consisting essentially of a surface active agent selected from the group consisting of an alkylbenzenesulfonate in which the alkyl group has 9 to 15 carbon atoms, an alkyl sulfate in which the alkyl group has 9 to 15 carbon atoms, an alkali metal or ammonium salt of the sulfated ethoxylates of a long chain alcohol and 3 to 5 molar proportions of ethylene oxide, amido carboxylic acids formed by condensing fatty acids of C3-C22 chain length with sarcosine, an alkanesulfonate, an alkoxyhydroxypropane sulfonate, a soap, propylene oxide condensed with propylene glycol to a molecular weight of about 6002500 further condensed with 10-90% ethylene oxide, simultaneously polymerized propylene oxide and ethylene oxide containing oxypropylene and oxyethylene groups, an alkyl phenol ethoxylated with 4-10 molar proportions of ethylene oxide and an ethoxylate of a C -C fatty alcohol and 5-30 molar proportions of oxyethylene groups and a detergent having the structure:

wherein R is an aliphatic saturated hydrocarbon group having 5-12 carbon atoms; Z is oxygen, sulfur or sulfoxide;ais1or2;mis0or1;nis0or1;m+nal1 occurrences is 1; and R' is H, CH OH or CH 3. A built detergent composition consisting essentially of 2-hydroxy-C C al-kyl glyceryl ether as a detergent and tetrapotassium pyrophosphate as a builder.

4. A dishwasher composition consisting essentially of u-decyl-a-hydroxyethyl glyceryl diether as a detergent and sodium alkylbenzenesulfonate in which the alkyl portion is linear C to C hydrocarbons as a surface active agent.

5. A dishwasher composition consisting essentially of 2-hydroxy-dodecyl glyceryl ether as a detergent and ammonium salt of a sulfated reaction product of 3.1 molar proportions of ethylene oxide and 1 mole of an alcohol mixture of about /3 n-tetradecanol and /3 n-dodecanol as a surface active agent.

6. A shampoo consisting essentially of 2-hydroxy-C C alkyl glyceryl ether as a detergent and ammonium lauryl sulfate as a surface active agent.

7. A composition with lime-soap dispersant Properties consisting essentially of 2-hydroxytetradecy1 glyceryl ether as :a detergent and sodium tallow-coconut soap as a surface active agent.

References Cited UNITED STATES PATENTS 2,768,956 10/1956 Scott 252-161 3,240,819 3/ 1966 Gaertner et al. 260-615 3,308,068 3/1967 Jones 252-161 3,350,460 10/ 1967 Lamberti 260-615 LEON D. ROSDOL, Primary Examiner.

P. E. WILLIS, Assistant Examiner.

US. Cl. X.R. 

